Yibo Qu

Publications (5)42.62 Total impact

• Article: Atypical cadherins Celsr1-3 differentially regulate migration of facial branchiomotor neurons in mice.

  Yibo Qu, Derrick M Glasco, Libing Zhou, Anagha Sawant, Aurélia Ravni, Bernd Fritzsch, Christine Damrau, Jennifer N Murdoch, Sylvia Evans, Samuel L Pfaff, Caroline Formstone, André M Goffinet, Anand Chandrasekhar, Fadel Tissir
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  ABSTRACT: During hindbrain development, facial branchiomotor neurons (FBM neurons) migrate from medial rhombomere (r) 4 to lateral r6. In zebrafish, mutations in planar cell polarity genes celsr2 and frizzled3a block caudal migration of FBM neurons. Here, we investigated the role of cadherins Celsr1-3, and Fzd3 in FBM neuron migration in mice. In Celsr1 mutants (knock-out and Crash alleles), caudal migration was compromised and neurons often migrated rostrally into r2 and r3, as well as laterally. These phenotypes were not caused by defects in hindbrain patterning or neuronal specification. Celsr1 is expressed in FBM neuron precursors and the floor plate, but not in FBM neurons. Consistent with this, conditional inactivation showed that the function of Celsr1 in FBM neuron migration was non-cell autonomous. In Celsr2 mutants, FBM neurons initiated caudal migration but moved prematurely into lateral r4 and r5. This phenotype was enhanced by inactivation of Celsr3 in FBM neurons and mimicked by inactivation of Fzd3. Furthermore, Celsr2 was epistatic to Celsr1. These data indicate that Celsr1-3 differentially regulate FBM neuron migration. Celsr1 helps to specify the direction of FBM neuron migration, whereas Celsr2 and 3 control its ability to migrate.
  Journal of Neuroscience 07/2010; 30(28):9392-401. · 7.11 Impact Factor
• Source

  Available from: David Gall

  Article: Maturation of "neocortex isole" in vivo in mice.

  Libing Zhou, David Gall, Yibo Qu, Cynthia Prigogine, Guy Cheron, Fadel Tissir, Serge N Schiffmann, Andre M Goffinet
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  ABSTRACT: How much neocortical development depends on connections remains elusive. Here, we show that Celsr3|Dlx mutant mice have no extrinsic neocortical connections yet survive to postnatal day 20, acquire a basic behavioral repertoire, and display spontaneous hyperactivity, with abnormal light/dark activity cycling. Except for hallmarks related to thalamic input, such as barrels in somatosensory cortex, cortical arealization and laminar maturation proceeded normally. However, the tangential extension of the mature cortex was diminished, with radial thickness less severely affected. Deep layer neurons were reduced in number, and their apical and basal dendritic arbors were blunted, with reduced synapse density. Interneurons reached the cortex, and their density was comparable with wild type. The excitability of mutant pyramidal neurons, measured in vitro in patch-clamp experiments in acute slices, was decreased. However, their firing activity in vivo was quite similar to the wild type, except for the presence of rapid firing exhaustion in some mutant neurons. Local field potential and electrocorticogram showed similar range of oscillations, albeit with higher frequency peaks and reduced left-right synchrony in the mutant. Thus, "protomap" formation, namely cortical lamination and arealization, proceed normally in absence of extrinsic connections, but survival of projection neurons and acquisition of mature morphological and some electrophysiological features depend on the establishment of normal cortical-subcortical relationships.
  Journal of Neuroscience 06/2010; 30(23):7928-39. · 7.11 Impact Factor
• Source

  Available from: Donatienne Tyteca

  Article: Lack of cadherins Celsr2 and Celsr3 impairs ependymal ciliogenesis, leading to fatal hydrocephalus.

  Fadel Tissir, Yibo Qu, Mireille Montcouquiol, Libing Zhou, Kouji Komatsu, Dongbo Shi, Toshihiko Fujimori, Jason Labeau, Donatienne Tyteca, Pierre Courtoy, Yves Poumay, Tadashi Uemura, Andre M Goffinet
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  ABSTRACT: Ependymal cells form the epithelial lining of cerebral ventricles. Their apical surface is covered by cilia that beat in a coordinated fashion to facilitate circulation of the cerebrospinal fluid (CSF). The genetic factors that govern the development and function of ependymal cilia remain poorly understood. We found that the planar cell polarity cadherins Celsr2 and Celsr3 control these processes. In Celsr2-deficient mice, the development and planar organization of ependymal cilia are compromised, leading to defective CSF dynamics and hydrocephalus. In Celsr2 and Celsr3 double mutant ependyma, ciliogenesis is markedly impaired, resulting in lethal hydrocephalus. The membrane distribution of Vangl2 and Fzd3, two key planar cell polarity proteins, was disturbed in Celsr2 mutants, and even more so in Celsr2 and Celsr3 double mutants. Our findings suggest that planar cell polarity signaling is involved in ependymal cilia development and in the pathophysiology of hydrocephalus, with possible implications in other ciliopathies.
  Nature Neuroscience 06/2010; 13(6):700-7. · 15.53 Impact Factor
• Article: Planar cell polarity cadherin Celsr1 regulates skin hair patterning in the mouse.

  Aurélia Ravni, Yibo Qu, André M Goffinet, Fadel Tissir
  Journal of Investigative Dermatology 05/2009; 129(10):2507-9. · 6.31 Impact Factor
• Article: Role of the atypical cadherin Celsr3 during development of the internal capsule.

  Libing Zhou, Yibo Qu, Fadel Tissir, Andre M Goffinet
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  ABSTRACT: The development of axonal tracts requires interactions between growth cones and the environment. Major bundles, particularly in the internal capsule, are completely defective in mice with constitutive mutation of Celsr3. In order to understand better how Celsr3 controls axonal tract formation, we generated a conditional allele that allowed inactivation of Celsr3 in different sectors of the forebrain. Effects of Celsr3 inactivation specifically in the telencephalon, in the ventral forebrain, or in the cortex, demonstrate essential roles for the gene, both in the neurons that project their axons to subcerebral targets such as the spinal cord, as well as in cells that guide projecting axons through the ventral forebrain. These observations provide unequivocal in vivo evidence that heterotypic interactions between axons and guidepost cells govern axonal path formation in mammals, and that Celsr3 plays a key role in this process. In absence of cortico-subcortical connections, mice can survive up to P20, allowing studies of behavior and cortical maturation. Mutant mice with defective corticospinal tracts survive normally and provide a model to evaluate in vivo the role of this tract in motor function in rodents.
  Cerebral Cortex 05/2009; 19 Suppl 1:i114-9. · 6.54 Impact Factor